Cover plate and a cover plate assembly for a concealed fire protection sprinkler

ABSTRACT

A cover plate is configured to be releasably connected to a fire protection sprinkler to conceal the fire protection sprinkler. The cover plate includes a first layer of metal on a first side of the cover plate that faces the concealed fire protection sprinkler, and a second layer of metal on a second side of the cover plate, the second side being opposite to the first side. The second layer of metal is bonded to the first layer and is more resistant to corrosion than is the first layer. In addition, the first layer is more thermally conductive than is the second layer. The fire protection sprinkler is configured to activate upon activation of a thermally responsive element. The thermally responsive element is a bulb or a soldered link.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of copending U.S. patent applicationSer. No. 18/070,557, filed Nov. 29, 2022, which is a continuation ofU.S. patent application Ser. No. 16/085,793, filed on Sep. 17, 2018, nowU.S. Pat. No. 11,541,638, issued on Jan. 3, 2023, which is a U.S.national stage application of PCT International Patent Application No.PCT/US2017/025818, filed Apr. 4, 2017, which claims priority from U.S.Provisional Patent Application No. 62/321,339, filed Apr. 12, 2016, eachof which is incorporated herein in its entirety.

FIELD OF THE INVENTION

Our invention relates generally to a cover plate and a cover plateassembly for concealing a fire protection sprinkler.

Conventional cover plates for fire protection sprinklers are typicallyused with deployable/drop-down deflector assemblies, such as thosedescribed in commonly-assigned U.S. Pat. No. 7,275,603 (Polan). Thesecover plates are soldered to a skirt. When the solder that attaches thecover plate to the skirt reaches the temperature rating of the coverplate, the solder melts and releases the cover plate from the skirt,exposing the sprinkler to the room being protected. These cover platesmust be made of a material that is readily soldered, and are typicallymade of a metal, such as copper. When cover plates made of copper areused in spaces or rooms, such as food processing facilities, that arewashed down frequently with water and, possibly, with chemicals,however, the copper surface of the cover plate can become tarnished orcorroded over time, giving the cover plates a discolored, unsightlyappearance.

One conventional method to address this undesirable appearance of thecopper cover plates is to provide a coat of paint over the surface ofthe cover plate facing the protected room. Frequent cleaning of theprotected room, however, can cause the coat of paint to erode, bubble,and/or strip over time, again giving the cover plates an unsightlyappearance.

In addition, the sensitivity of a fire protection sprinkler can beaffected by covering the fire protection sprinkler with a cover plate.As such, concealed fire protection sprinklers are designed and tested tohave a predetermined sensitivity when configured with an approvedconcealed sprinkler cover plate. Conventionally, such concealed fireprotection sprinklers and cover plates are tested according to relevantstandards promulgated by Underwriters Laboratories, Inc. (UL), ofNorthbrook, Illinois, United States.

Current UL listing criteria require that quick response (QR) fireprotection sprinklers and QR extended coverage fire protectionsprinklers for light hazard occupancies, for example, must achievecomplete activation of the cover plate and a thermally-responsiveelement (e.g., a bulb or a soldered link) within seventy-five (75)seconds when tested in accordance with UL Standard 199, Section 31,entitled “Room heat test for QR and QR extended coverage sprinklers.”The current UL listing criteria also require that QR fire protectionsprinklers and QR extended coverage fire protection sprinklers forordinary hazard occupancies, for example, must achieve completeactivation of the cover plate and the thermally-responsive element(e.g., a bulb or a soldered link) within fifty-five (55) seconds whentested in accordance with UL Standard 199, Section 31, entitled “Roomheat test for QR and QR extended coverage sprinklers.”

SUMMARY OF THE INVENTION

To address the problems described above, our invention provides a coverplate for a concealed fire protection sprinkler, the cover plate havinga first layer of metal on a first side of the cover plate that faces thefire protection sprinkler, and a second layer of metal on a side of thecover plate that faces an enclosure to be protected, in which the firstlayer of metal is more thermally conductive than the second layer, andthe second layer is more resistant to corrosion than is the first layer.

More specifically, our invention provides a cover plate that isreleasably connected to a concealed fire protection sprinkler, and thatis configured to conceal the fire protection sprinkler. The cover plateincludes a first layer of metal on a first side of the cover plate thatfaces the concealed fire protection sprinkler, and a second layer ofmetal on a second side of the cover plate, the second side beingopposite to the first side. The second layer of metal is more resistantto corrosion than the first layer, and is bonded to the first layer. Thefirst layer is more thermally conductive than the second layer, and, inat least one embodiment, a thickness of the first layer is greater thana thickness of the second layer.

By virtue of our invention, it is possible to provide a cover platehaving corrosion resistance due to the nature of the second layer ofmetal on a room side of the fire protection sprinkler, while maintaininga response time of the fire protection sprinkler due to the high thermalconductivity of the first layer of metal.

In one embodiment, the first layer of metal comprises copper, and thesecond layer of metal comprises stainless steel. In another embodiment,the thickness of the first layer is at least 16% of the total thicknessof the first and second layers. In yet another, the thickness of thefirst layer is at least 80% of the total thickness of the first andsecond layers.

By virtue of our invention, it is possible to provide a cover plate thatmeets the UL criteria, for example, discussed above for QR fireprotection sprinklers and QR extended coverage fire protectionsprinklers for light and ordinary hazard occupancies, while alsoproviding a corrosive resistant cover plate.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A shows a side cross-sectional view of a cover plate assembly fora concealed fire protection sprinkler, according to an embodimentdescribed herein, and FIG. 1B is a detail view of a portion of the coverplate assembly shown in FIG. 1A.

FIG. 2 shows a back view of the cover plate assembly shown in FIG. 1A.

FIG. 3 shows a front view of the cover plate assembly shown in FIG. 1A

FIG. 4 shows a side cross-sectional view of the cover plate assemblyshown in FIG. 1A, including a gasket seal.

FIG. 5 shows a back view of the cover plate assembly shown in FIG. 4 .

FIG. 6 shows the cover plate assembly shown in FIG. 1A and a concealedfire protection sprinkler installed in a ceiling.

Any reference numeral that appears in different figures represents thesame element in those figures, even if that element is not describedseparately with respect to each figure.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 1A shows a side cross-sectional view of a cover plate assembly 100for a concealed fire protection sprinkler (300 in FIG. 6 ), according toone embodiment of the invention. The cover plate assembly 100 includes acover plate 110, an escutcheon 120, and a frame 130, all aligning alonga central axis. The escutcheon 120 is cylindrical, and has acircumferential, annular flange 150 on an outwardly facing end (thelower end in FIG. 1A). The escutcheon 120 is formed of metal, such ascopper or a copper alloy. The escutcheon 120 includes perforations 121on outer walls for installation with the fire protection sprinkler 300.In other embodiments, the escutcheon 120 may include threading forinstallation with the fire protection sprinkler 300.

The cover plate 110 is flat and circular, and includes a first layer 112and a second layer 111. The first layer 112 is on a first side of thecover plate 110 that faces the escutcheon 120 and the fire protectionsprinkler 300. The second layer 111 is on a second side of the coverplate 110, opposite to the first side of the cover plate 110, and facinga room to be protected by the fire protection sprinkler 300. The firstlayer 112 and the second layer 111 are bonded together.

The first layer 112 is formed of a metal having high thermalconductivity, such as copper or a copper alloy. The second layer 111 isformed of a metal having high resistance to corrosion, such as stainlesssteel. Of course, the materials used to form the first layer 112 and thesecond layer 111 of the cover plate 110 are not limited to copper andstainless steel, and, in other embodiments, the cover plate 110 can beformed of other materials, as long as a material forming the first layer112 has high thermal conductivity and a material forming the secondlayer 111 has high resistance to corrosion.

Other embodiments include the first layer 112 comprising bronze, brass,nickel, beryllium nickel, or sterling silver, and the second layer 111comprising titanium, molybdenum, alloys, such as those sold under thetrademark Incoloy® (examples of such alloys include UNS S67956 and UNSN08020) (Incoloy® is a registered trademark of Huntington AlloysCorporation, Huntington, West Virginia), ortitanium-zirconium-molybdenum (TZM) alloy.

The frame 130 is formed of a metal, such as copper or a copper alloy,and includes multiple tabs 131 and a spring 132. The frame 130 is in theshape of a flat ring, and the multiple tabs 131 are formed on the frame130 by downwardly bending outer sections of the ring of the frame 130into L-shapes.

The frame 130 is mounted and fixed to the escutcheon 120 around a bottomperiphery of the escutcheon flange 150 using, for example, an adhesive.The cover plate 110 is attached to the frame 130 with solder between thebottom of each of the multiple tabs 131 and the first layer 112 on thefirst side of the cover plate 110, using a solder that is designed tomelt at a predetermined temperature, for example, 135° F., to allow forrelease of the cover plate 110 and to expose the fire protectionsprinkler 300. The spring 132 applies a downward force against the coverplate 110 once the cover plate 110 is soldered to the frame 130. Theapplication of force by the spring 132 facilitates the release of thecover plate 110 once the solder has melted.

FIG. 1B is a detail view of the cross-sectional view of the cover plateassembly 100 shown in FIG. 1A. The view of FIG. 1B provides a detailedlook at the first layer 112 and the second layer 111 of the cover plate110. As shown in FIG. 1B, a dimension of the first layer 112 (in thisexample, the thickness of the first layer 112) is greater than that ofthe second layer 111. The second layer 111 is formed of a material thatis more resistant to corrosion than the material that forms the firstlayer 112. Also, the first layer 112 is more thermally conductive thanthe second layer 111. In other words, the first layer 112 has a higherthermal conductivity than that of the second layer 111.

In one embodiment, the thickness of the first layer 112 is at least 16%of the combined thicknesses of the first layer 112 and the second layer111 (i.e., the total thickness of the cover plate 110). In anotherembodiment, the thickness of the first layer 112 is at least 80% of thetotal thickness of the cover plate 110. It is within the scope of theinvention for the thickness of the first layer 112 to be in the rangefrom 16% to 80%, inclusive, of the combined thicknesses of the firstlayer 112 and the second layer 111.

In one embodiment, the first layer 112 of the cover plate 110 iscomprised of copper with a thickness of 0.0096 inches (0.24 mm), and thesecond layer 111 of the cover plate 110 is comprised of stainless steelwith a thickness of 0.0024 inches (0.061 mm). In this embodiment, thecover plate 110 is comprised of 80% copper and 20% stainless steel(referring to the relation of the thickness of the layers, not toweight).

The cover plate 110 of the above-described embodiment successfullyreleased in under forty-five (45) seconds with cover plates havingtemperature ratings ranging from 135° F. to 165° F.

FIG. 3 shows a view of the second layer 111 on the second or exteriorside of the cover plate 110 that faces the room to be protected. Asshown in FIG. 3 , the cover plate 110 does not require painting and, infact, must not be painted after installation. In addition, the coverplate 110 has an aesthetically pleasing look, or finish, for example, ofstainless steel.

FIGS. 4 and 5 show a side section view and a back view, respectively, ofthe cover plate assembly 100 shown in FIG. 1A, including a gasket seal201. The gasket seal 201 is formed around the cover plate 110 along thecircumference of the cover plate 110. The gasket seal 201 limits theinfiltration of gases or liquids from the room to be protected to aspace above the cover plate 110.

FIG. 6 shows the cover plate assembly 100 shown in FIG. 1A and theconcealed fire protection sprinkler 300 installed in a ceiling 430,according to an embodiment. As shown in FIG. 6 , the fire protectionsprinkler 300 may be installed within a support cup 320, the escutcheon120, and the cover assembly 100 to form a concealed configuration. Theescutcheon 120 is installed with a press or threaded fit into the ridgedouter surface walls 330 of the support cup 320.

As described above with reference to FIG. 1A, the cover plate 110 ismounted on raised portions (e.g., the multiple tabs 131 of the frame 130in FIG. 1A) around the periphery of the escutcheon flange 150. As alsodescribed above, the cover plate 110 is attached to the multiple tabs131 with solder that is designed to melt at a predetermined temperature,e.g., 135° F., to allow for release of the cover plate 110. The raisedportions 131 create a gap or a space between the cover plate 110 and theescutcheon 120 that allows air flow to reach the fire protectionsprinkler 300. The release of the cover plate 110 allows a deflector340, mounted on the fire protection sprinkler 300, to drop down into adeployed position. At a second predetermined temperature, e.g., 165° F.,a fusible soldered link 350 of the fire protection sprinkler 300separates to initiate the flow of a fluid from the fire protectionsprinkler 300.

To install the fire protection sprinkler 300, the support cup 320,having a diameter of, e.g., 2.28 inches (57.91 mm), is inserted into acavity in the ceiling 430, the cavity having a diameter of, e.g., about2.63 inches (66.68 mm), and a threaded base 310 of the fire protectionsprinkler 300 is connected to an output fitting 435 of a conduit 440.The escutcheon 120 and the cover plate 110 are then installed in thesupport cup 320, so that the escutcheon flange 150 rests on the outersurface of the ceiling 430 (the outer surface of the cover plate 110 isabout 0.188 inch (4.77 mm) from the surface of the ceiling 430 due tothe gap between the escutcheon flange 150 and the cover plate 110).

The support cup 320 and the escutcheon 120 are configured to allow foran adjustment to accommodate variations in the distance between a face450 of the output fitting 435 and the surface of the ceiling 430,referred to as a “field adjustment.” The field adjustment is sometimesneeded because the deflector 340 must be properly located below theceiling 430 in the deployed position, but positioning of the sprinklerconduits 440 precisely with respect to the ceiling 430 surface isdifficult, due to the practicalities of building construction. To ensurethe correct positioning of the deployed deflector 340, the distancebetween the face 450 of the output fitting 435 and the ceiling 430should not be more than 2 inches (50.8 mm).

The field adjustment is achieved by allowing the escutcheon 120 to bepositioned with a varying degree of overlap with the outer walls 330 ofthe support cup 320. The support cup 320 and the escutcheon 120 areconfigured so that any secure engagement between these componentsresults in a proper position for the deflector 340 upon deployment.

The amount of field adjustment, in this example 0.5 inch (12.7 mm), isdetermined by the length of rods 360 of deflector support members 380 ofthe fire protection sprinkler 300, because the length of the rods 360determines the amount of variation that can be accommodated in theposition of the conduit 440 relative to the ceiling line 430. In otherwords, the rods 360 may be completely retracted within a respectivehousing member 370 before deployment, such as when the conduit 440 and,therefore, the fire protection sprinkler 300 are positioned as close aspossible to the ceiling line 430. Alternatively, the rods 360 may benearly ¾ extended before deployment, such as when the conduit 440 ispositioned as far as possible above the ceiling line 430. The length ofthe rods 360, in turn, determines the height of the outer walls 330 ofthe support cup 320. Thus, the outer walls 330 of the support cup 320must have a height of slightly more than 0.5 inch (12.7 mm) in theembodiment described herein.

Configuring deflector support members 380 that include the housingmembers 370 and the rods 360, such that the rods 360 extend through thehousing members 370 and the flange 150, allows for the use of ashallower support cup 320, because the depth of the support cup 320 isprimarily determined by the length of the rods 360. This, in turn,results in the thermally-responsive element, for example, the fusiblesoldered link 350, being located closer to the ceiling 430, therebyimproving sprinkler sensitivity. In contrast, in conventional concealedfire protection sprinklers, guide pins coupled to the deflector aregenerally positioned below the flange, requiring a deeper support cupbecause the depth of the support cup is determined by the length of theguide pins plus the flange thickness. Consequently, thethermally-responsive element is located farther from the ceiling,resulting in reduced sprinkler sensitivity.

Based on our findings, stainless steel is not typically used in coverplates because it has a lower thermal conductivity than copper (i.e.,stainless steel is more insulating than copper), so using stainlesssteel instead of copper slows the heating of the solder and, therefore,slows the operation of the fire protection sprinkler. In addition, wehave found that stainless steel is more difficult to solder than copper.

By virtue of the foregoing arrangement, our invention provides a coverplate, for example, a composite copper/stainless steel cover plate thatprovides corrosion resistance on the room side of a fire protectionsprinkler, while maintaining the response time of the fire protectionsprinkler due to the high thermal conductivity of the copper backing.

More specifically, the foregoing arrangement meets all of the current ULlisting criteria set forth in UL Standard 199, Section 31. For example,the foregoing arrangement meets the requirement that quick response (QR)fire protection sprinklers and QR extended coverage fire protectionsprinklers for light hazard occupancies, for example, must achievecomplete activation of the cover plate and a thermally-responsiveelement (e.g., a bulb or a soldered link) within seventy-five (75)seconds, and the requirement that QR fire protection sprinklers and QRextended coverage fire protection sprinklers for ordinary hazardoccupancies, for example, must achieve complete activation of the coverplate and the thermally-responsive element (e.g., a bulb or a solderedlink) within fifty-five (55) seconds, when tested in accordance with ULStandard 199, Section 31, entitled “Room heat test for QR and QRextended coverage sprinklers.”

While the present invention has been described with respect to what are,at present, considered to be the preferred embodiments, it is to beunderstood that the invention is not limited to the disclosedembodiments. To the contrary, the invention is intended to cover variousmodifications and equivalent arrangements included within the spirit andscope of the appended claims.

What I claim is:
 1. A cover plate assembly for covering a fireprotection sprinkler, the cover plate assembly comprising: (a) acylindrical escutcheon removably attached to a support cup by apress-fit or a threaded connection into outer walls of the support cup,the escutcheon having a circumferential annular flange, and perforationson outer walls for installation with the fire protection sprinkler, theescutcheon being made of copper or a copper alloy; (b) a metal framebeing made of copper or a copper alloy and having multiple tabs, themultiple tabs being formed on the metal frame by downwardly bendingouter sections of the metal frame into L-shapes, the metal frame beingmounted to the circumferential annular flange of the escutcheon; and (c)a cover plate releasably connected to the multiple tabs of the metalframe around the perimeter of the circumferential annular flange of theescutcheon, the metal frame applying a downward force against the coverplate when the cover plate assembly is attached to the metal frame, thecover plate being configured to conceal the fire protection sprinkler,the cover plate being attached to the metal frame with solder betweenthe bottom of each of the multiple tabs and a first layer of metal on afirst side of the cover plate, the solder being designed to melt at afirst predetermined temperature to allow for release of the cover plateto expose the fire protection sprinkler, and the cover plate having anentire length from one end to an opposite end and comprising: (i) thefirst layer of metal on the first side of the cover plate extendingalong the length of the cover plate from the one end of the cover plateto the opposite end of the cover plate, the first side of the coverplate having the first layer of metal directly facing the concealed fireprotection sprinkler, wherein the first layer of metal comprises acopper alloy; and (ii) a second layer of metal on a second side of thecover plate, the second side being opposite to the first side andextending along the length of the cover plate from the one end of thecover plate to the opposite end of the cover plate, the second layer ofmetal being more resistant to corrosion than is the first layer, andbeing bonded to the first layer, wherein the second layer comprises astainless steel alloy, wherein (1) the first layer of metal facing thefire protection sprinkler is more thermally conductive than is thesecond layer, and (2) the first layer of metal has a greater thicknessthan that of the second layer, and wherein the first predeterminedtemperature is less than a second predetermined temperature, at whichthe fire protection sprinkler is configured to activate upon activationof a thermally responsive element.
 2. The cover plate assembly accordingto claim 1, wherein the thickness of the first layer is at least 80% ofthe combined thickness of the first and second layers.
 3. The coverplate assembly according to claim 1, wherein the second layer of metalon the second side of the cover plate faces a room to be protected bythe fire protection sprinkler.
 4. The cover plate assembly according toclaim 1, wherein the first predetermined temperature is 135° F.
 5. Thecover plate assembly according to claim 1, wherein the secondpredetermined temperature is 165° F.
 6. The cover plate assemblyaccording to claim 1, wherein the cover plate is successfully releasedin under forty-five (45) seconds with cover plates having temperatureratings ranging from 135° F. to 165° F.
 7. The cover plate assemblyaccording to claim 1, wherein the cover plate is unpainted afterinstallation.
 8. The cover plate assembly according to claim 1, furthercomprising a sealing gasket provided around a circumference of the coverplate.
 9. The cover plate assembly according to claim 8, wherein thesupport cup and the escutcheon are configured to allow for a fieldadjustment to accommodate variations in a distance between a face of anoutput fitting of the fire protection sprinkler and a surface of aceiling to which the cover plate assembly is installed.
 10. The coverplate assembly according to claim 8, wherein the field adjustment isachieved by allowing the escutcheon to be positioned with a varyingdegree of overlap with the outer walls of the support cup.
 11. The coverplate assembly according to claim 1, wherein installation of the fireprotection sprinkler allows the thermally responsive element to bespaced from the ceiling, resulting in improved sprinkler sensitivity.12. The cover plate assembly according to claim 1, further comprisingdeflector support members that include rods.
 13. The cover plateassembly according to claim 12, wherein varying the lengths of the rodsdetermines an amount of variation that can be accommodated ininstallation of the fire protection sprinkler.
 14. The cover plateassembly according to claim 1, wherein the composite of the copper alloyand the stainless steel cover plate provides corrosion resistance on aroom side of the fire protection sprinkler while maintaining responsetime of the fire protection sprinkler due to the higher thermalconductivity of the copper alloy.
 15. The cover plate assembly accordingto claim 1, wherein the metal frame also includes a spring, andapplication of force by the spring facilitates release of the coverplate once the solder has melted.
 16. The cover plate assembly accordingto claim 15, wherein the release of the cover plate allows a deflectorof the fire protection sprinkler to drop down into a deployed position.17. The cover plate assembly according to claim 1, wherein the thermallyresponsive element is a bulb or a soldered link.
 18. A concealed fireprotection sprinkler arrangement comprising: (A) a fire protectionsprinkler comprising: (a) a thermally responsive element positioned toreleasably retain a seal cap; (b) a plurality of deflector supportmembers extending from a flange; and (c) a deflector connected to theplurality of deflector support members; (B) a support cup having outerwalls and configured to support the fire protection sprinkler; and (C) acover plate assembly for covering the fire protection sprinkler, thecover plate assembly comprising: (a) a cylindrical escutcheon removablyattached to the support cup by a press-fit or a threaded connection intothe outer walls of the support cup, the escutcheon having acircumferential annular flange, and perforations on outer walls forinstallation with the fire protection sprinkler, the escutcheon beingmade of copper or a copper alloy; (b) a metal frame being made of copperor a copper alloy and having multiple tabs, the multiple tabs beingformed on the metal frame by downwardly bending outer sections of themetal frame into L-shapes, the metal frame being mounted to thecircumferential annular flange of the escutcheon; and (c) a cover platereleasably connected to the multiple tabs of the metal frame around theperimeter of the circumferential annular flange of the escutcheon, themetal frame applying a downward force against the cover plate when thecover plate assembly is attached to the metal frame, the cover platebeing configured to conceal the fire protection sprinkler, the coverplate being attached to the metal frame with solder between the bottomof each of the multiple tabs and a first layer of metal on a first sideof the cover plate, the solder being designed to melt at a firstpredetermined temperature to allow for release of the cover plate toexpose the fire protection sprinkler, and the cover plate having anentire length from one end to an opposite end and comprising: (i) thefirst layer of metal on the first side of the cover plate extendingalong the length of the cover plate from the one end of the cover plateto the opposite end of the cover plate, the first side of the coverplate having the first layer of metal directly facing the concealed fireprotection sprinkler, wherein the first layer of metal comprises acopper alloy; and (ii) a second layer of metal on a second side of thecover plate, the second side being opposite to the first side andextending along the length of the cover plate from the one end of thecover plate to the opposite end of the cover plate, the second layer ofmetal being more resistant to corrosion than is the first layer, andbeing bonded to the first layer, wherein the second layer comprises astainless steel alloy, wherein (1) the first layer of metal facing thefire protection sprinkler is more thermally conductive than is thesecond layer, and (2) the first layer of metal has a greater thicknessthan that of the second layer, and wherein the first predeterminedtemperature is less than a second predetermined temperature, at whichthe fire protection sprinkler is configured to activate upon activationof a thermally responsive element.
 19. The concealed sprinklerarrangement according to claim 18, wherein the thickness of the firstlayer is at least 80% of the combined thickness of the first and secondlayers.
 20. The concealed sprinkler arrangement according to claim 18,wherein the second layer of metal on the second side of the cover platefaces a room to be protected by the fire protection sprinkler.
 21. Theconcealed fire sprinkler arrangement according to claim 18, wherein thefirst predetermined temperature is 135° F.
 22. The concealed firesprinkler arrangement according to claim 18, wherein the secondpredetermined temperature is 165° F.
 23. The concealed fire sprinklerarrangement according to claim 18, wherein the cover plate issuccessfully released in under forty-five (45) seconds with cover plateshaving temperature ratings ranging from 135° F. to 165° F.
 24. Theconcealed fire sprinkler arrangement according to claim 18, wherein thecover plate is unpainted after installation.
 25. The concealed firesprinkler arrangement according to claim 18, further comprising asealing gasket provided around a circumference of the cover plate. 26.The concealed fire sprinkler arrangement according to claim 25, whereinthe support cup and the escutcheon are configured to allow for a fieldadjustment to accommodate variations in a distance between a face of anoutput fitting of the fire protection sprinkler and a surface of aceiling to which the cover plate assembly is installed.
 27. Theconcealed fire sprinkler arrangement according to claim 26, wherein thefield adjustment is achieved by allowing the escutcheon to be positionedwith a varying degree of overlap with the outer walls of the supportcup.
 28. The concealed fire sprinkler arrangement according to claim 18,wherein installation of the fire protection sprinkler allows thethermally responsive element to be spaced from the ceiling, resulting inimproved sprinkler sensitivity.
 29. The concealed fire sprinklerarrangement according to claim 18, further comprising deflector supportmembers that include rods.
 30. The concealed fire sprinkler arrangementaccording to claim 29, wherein varying the lengths of the rodsdetermines the amount of variation that can be accommodated ininstallation of the fire protection sprinkler.
 31. The concealed firesprinkler arrangement according to claim 18, wherein the composite ofthe copper alloy and the stainless steel cover plate provides corrosionresistance on a room side of the fire protection sprinkler whilemaintaining response time of the fire protection sprinkler due to thehigher thermal conductivity of the copper alloy.
 32. The concealed firesprinkler arrangement according to claim 18, wherein the metal framealso includes a spring, and application of force by the springfacilitates release of the cover plate once the solder has melted. 33.The concealed fire sprinkler arrangement according to claim 32, whereinthe release of the cover plate allows the deflector of the fireprotection sprinkler to drop down into a deployed position.
 34. Theconcealed fire protection sprinkler according to claim 18, wherein thethermally responsive element is a bulb or a soldered link.